Segment sensitive scheduling

ABSTRACT

Systems and methods of scheduling sub-carriers in an OFDMA system in which a scheduler takes into account channel conditions experienced by the communication devices to optimize channel conditions. The scheduler can partition a set of sub-carriers spanning an operating bandwidth into a plurality of segments. The segments can include a plurality of global segments that each includes a distinct non-contiguous subset of the sub-carriers spanning substantially the entire operating bandwidth. One or more of the global segments can be further partitioned into a plurality of local segments that each has a bandwidth that is less than a channel coherence bandwidth. The scheduler determines channel characteristics experienced by each communication device via reporting or channel estimation, and allocates one or more segments to communication links for each device according to the channel characteristics.

CLAIM OF PRIORITY UNDER 35 U.S.C. §120

The present application for patent is a divisional of patent application Ser. No. 11/260,924 entitled “CHANNEL SENSITIVE SCHEDULING” filed Oct. 27, 2005, pending, and assigned to the assignee hereof and hereby expressly incorporated by reference herein, and claims priority to Provisional Application No. 60/710,461 entitled “CHANNEL SENSITIVE SCHEDULING” filed Aug. 22, 2005.

REFERENCE TO CO-PENDING APPLICATIONS FOR PATENT

The present application for patent is related to the following co-pending U.S. patent applications:

“Shared Signaling Channel” by having Attorney Docket No. 060058, filed concurrently herewith, assigned to the assignee hereof, and expressly incorporated by reference herein; and

“Mobile Wireless Access System” having Attorney Docket No. 060081, filed concurrently herewith, assigned to the assignee hereof, and expressly incorporated by reference herein.

BACKGROUND OF THE INVENTION

1. Field of the Disclosure

The disclosure relates to the field of wireless communications. More particularly, the disclosure relates to scheduling of resources in a wireless communication system.

2. Description of Related Art

Communication devices operating in wireless communication systems can be affected by drastic changes in the channel conditions experienced by communication device. The channel conditions can be affected by extraneous interferers and can be affected by changes in the physical relationship and terrain separating a wireless transmitter from a receiver.

It is known that a wireless signal originating at the transmitter is attenuated by the physical distance to the receiver. Additionally, it is known that multipath signals from the transmitter to the receiver can result in fading of the channel.

A wireless communication system can compensate for attenuation by increasing transmit power or by increasing modulation or coding gain associated with the transmit signal. A wireless communication system may partially compensate for multipath fading by implementing a broadband signal that allows the receiver to separately identify multipath signals.

A wireless communication system implementing frequency division multiplexing can operate over a relatively wide frequency band. The operating band may be sufficiently wide that distinct communication devices operating at the same location but at different operating frequencies may experience substantially different channel conditions and channel fading. Additionally, each communication device may not operate with a sufficiently broad band signal to allow the device to compensate for multipath fades.

It is desirable to have the ability to communicate in a frequency division multiplex communication system with multiple communication devices in a manner that compensates for, or otherwise substantially eliminates the effects of frequency selective channel conditions.

BRIEF SUMMARY OF THE INVENTION

Systems and methods of scheduling sub-carriers in an OFDMA system are disclosed, in which a scheduler takes into account channel conditions experienced by the communication devices to optimize channel conditions. The scheduler can partition a set of sub-carriers spanning an operating bandwidth into a plurality of segments. The segments can include a plurality of global segments that each includes a distinct non-contiguous subset of the sub-carriers spanning substantially the entire operating bandwidth. One or more of the global segments can be further partitioned into a plurality of local segments that each has a bandwidth that is less than a channel, carrier, or coherence bandwidth. The scheduler determines channel characteristics experienced by each communication device via reporting or channel estimation, and allocates one or more segments to communication links for each device according to the segment characteristics.

The disclosure includes a method of segment sensitive scheduling in an Orthogonal Frequency Division Multiple Access (OFDMA) communication system including a plurality of sub-carriers spanning an operating frequency band. The method includes partitioning the operating frequency band into a plurality of segments, determining a segment preference indicative of a preferred segment based upon channel characteristics experienced by a receiver, and assigning a subset of sub-carriers within the preferred segment to a particular communication link associated with the segment preference.

The disclosure includes a method of segment sensitive scheduling that includes partitioning the operating frequency band into a plurality of segments, determining user data constraints, assigning sub-carriers from a global segment having a non-contiguous subset of sub-carriers spanning a substantial fraction of the operating band if the user data constraints include a data bandwidth requirement greater than a coherent bandwidth of a carrier, segment, or the like determining, if the data bandwidth requirement is not greater than the coherent bandwidth of a carrier, segment or the like, a segment preference indicative of a preferred local segment based upon channel characteristics experienced by a receiver, the preferred local segment selected from a plurality of local segments, each of the plurality of local segments having a bandwidth less than the coherent bandwidth, and assigning a subset of sub-carriers within the preferred local segment to a communication link associated with the segment preference.

The disclosure includes an apparatus for segment sensitive scheduling. The apparatus includes a receiver module configured to receive a pilot signal, a channel estimator coupled to the receiver and configured to determine a channel estimate corresponding to each of a plurality of segments spanning the operating frequency band based on the pilot signal, each of the segments having a bandwidth less than a coherent bandwidth, a signal mapper configured to map serial data symbols to a subset of the plurality of sub-carriers in the OFDMA communication system, and a resource scheduler coupled to the channel estimator and configured to determine a first preferred segment based on the channel estimates, select the subset of the plurality of sub-carriers from within the first preferred segment, and further configured to control the signal mapper to map the data symbols to the subset of the plurality of sub-carriers.

The disclosure includes an apparatus for segment sensitive scheduling that includes a receiver module configured to receive a reverse link pilot signal and at least one channel characteristic reporting message, and a scheduler coupled to the receiver module and configured to determine, based on the reverse link pilot signal, a channel characteristic corresponding to each of a plurality of segments spanning the operating frequency band, each of the segments having a bandwidth less than a coherent bandwidth, the scheduler configured to determine a reverse link assignment based on the channel characteristics and further configured to determine a forward link resource assignment based on the at least one channel characteristic reporting message.

The disclosure includes an apparatus for segment sensitive scheduling that includes means for determining a segment preference indicative of a preferred segment from a plurality of segments substantially spanning the operating band based upon channel characteristics experienced by a receiver, and means for assigning a subset of sub-carriers within the preferred segment to a particular communication link associated with the segment preference.

The disclosure includes a method of reporting segment characteristics. The method includes receiving a pilot signal, determining a segment characteristic corresponding to each of a plurality of segments spanning the operating band, each segment having a bandwidth less than a coherent bandwidth, determining a preferred segment from the plurality of segments, comparing the channel characteristic corresponding to the preferred segment to a reporting threshold, and generating a reporting message based on the preferred segment if the channel characteristic corresponding to the preferred segment exceeds the reporting threshold.

BRIEF DESCRIPTION OF THE DRAWINGS

The features, objects, and advantages of embodiments of the disclosure will become more apparent from the detailed description set forth below when taken in conjunction with the drawings, in which like elements bear like reference numerals.

FIG. 1 is a simplified functional block diagram of an embodiment of a communication system having segment sensitive scheduling.

FIG. 2 is a simplified functional block diagram of an embodiment of a transmitter with segment sensitive scheduling.

FIG. 3 is a simplified functional block diagram of an embodiment of a receiver in a system implementing segment sensitive scheduling.

FIG. 4 is a simplified flowchart of an embodiment of a method of segment sensitive scheduling.

FIG. 5 is a simplified flowchart of an embodiment of a method of segment characteristic reporting in a system implementing segment sensitive scheduling.

DETAILED DESCRIPTION OF THE INVENTION

Segment sensitive scheduling of sub-carrier resources in an Orthogonal Frequency Division Multiple Access (QFDMA) communication system provides for a form of multi-user frequency diversity. A segment sensitive scheduler operates to schedule communication links with communication devices on available sub-carriers in the OFDMA system having maximum gain.

Frequency selectivity is a common characteristic of broadband wireless communication systems. Users with the same average channel strength may have quite different channel strength at particular frequency tones. The interference a user observes is in general also frequency selective. Hence, it would be desirable for users to communicate over the frequency tones with high signal level or low interference level depending on user data requirements and information resources of the system. The segment sensitive scheduling schemes discussed herein implement scheduling frequency tones, such as sub-carriers in an OFDMA system, based on the user frequency or channel characteristics under overhead and latency constraints.

One set of beneficiaries of segment sensitive scheduling include users with low signal to noise ratio (SNR), limited assignment size and low mobility. According to information theory, SNR improvement translates into capacity gain through a logarithmic function, hence, the capacity gain is larger if the SNR is low. In practical systems, the capacity of high SNR users may also be limited by the capacity of the highest order modulation and coding scheme that saturates at certain SNR, which diminishes the improvements due to further improvement in SNR. High data rate users require transmission of signals over a large fraction of the total bandwidth, which reduces the potential gain of scheduled transmission over average segment SNR. The scheduling and transmission delay can make it difficult to schedule high mobility users on their preferred tones based on past channel observations. Fortunately, many users in a wide area network satisfy the SNR, assignment size, and mobility requirements to benefit from segment sensitive scheduling.

A scheduler in an OFDMA system can be configured to schedule forward link communications from a base station to a user terminal, reverse link communications from a user terminal to a base station, or a combination of forward link and reverse link communications. A scheduler can perform forward link scheduling independent of reverse link scheduling. In other embodiments, the scheduler can relate forward link scheduling to reverse link scheduling.

The scheduler operates to schedule channel resources based, at least in part, on channel characteristics experienced by the communication devices. In one embodiment, the scheduler can determine the channel characteristics based on one or more channel quality indicator (CQI) included in one or more reporting messages communicated from a communication device to the scheduler. In another embodiment, the scheduler can be configured to determine the channel characteristics through channel estimation. In another embodiment, the scheduler can determine the channel characteristics using a combination of reporting messages and channel estimation.

FIG. 1 is a simplified functional block diagram of an embodiment of a wireless communication system 100 configured to schedule resources based on channel characteristics. The system 100 includes one or more fixed elements that can be in communication with a user terminal 110. Although the description of the system 100 of FIG. 1 generally describes a wireless telephone system or a wireless data communication system, the system 100 is not limited to implementation as a wireless telephone system or a wireless data communication system nor is the system 100 limited to having the particular elements shown in FIG. 1.

The user terminal 110 can be, for example, a wireless telephone configured to operate according to one or more communication standards. The user terminal 110 can be a portable unit, a mobile unit, or, a stationary unit. The user terminal 110 may also be referred to as a mobile unit, a mobile terminal, a mobile station, user equipment, a portable, a phone, and the like. Although only a single user terminal 110 is shown in FIG. 1, it is understood that a typical wireless communication system 100 has the ability to communicate with multiple user terminals 110.

The user terminal 110 typically communicates with one or more base stations 120 a or 120 b, here depicted as sectored cellular towers. Other embodiments of the system 100 may include access points in place of the base stations 120 a and 120 b. In such a system 100 embodiment, the BSC 130 and MSC 140 may be omitted and may be replaced with one or more switches, hubs, or routers.

As used herein, a base station may be a fixed station used for communicating with the terminals and may also be referred to as, and include some or all the functionality of, an access point, a Node B, or some other terminology. An access terminal may also be referred to as, and include some or all the functionality of, a user equipment (UE), a wireless communication device, terminal, a mobile station or some other terminology.

The user terminal 110 will typically communicate with the base station, for example 120 b, that provides the strongest signal strength at a receiver within the user terminal 110. Each of the base stations 120 a and 120 b can include a scheduler configured to assign and schedule the segment resources. The one or more base stations 120 a-120 b can be configured to schedule the channel resources used in the forward link, reverse link, or both links.

Each of the base stations 120 a and 120 b can be coupled to a Base Station Controller (BSC) 140 that routes the communication signals to and from the appropriate base stations 120 a and 120 b. The BSC 140 is coupled to a Mobile Switching Center (MSC) 150 that can be configured to operate as an interface between the user terminal 110 and a Public Switched Telephone Network (PSTN) 150. In another embodiment, the system 100 can implement a Packet Data Serving Node (PDSN) in place or in addition to the PSTN 150. The PDSN can operate to interface a packet switched network, such as network 160, with the wireless portion of the system 100.

The MSC 150 can also be configured to operate as an interface between the user terminal 110 and a network 160. The network 160 can be, for example, a Local Area Network (LAN) or a Wide Area Network (WAN). In one embodiment, the network 160 includes the Internet. Therefore, the MSC 150 is coupled to the PSTN 150 and network 160. The MSC 150 can also be configured to coordinate inter-system handoffs with other communication systems (not shown).

The wireless communication system 100 can be configured as an OFDMA system with communications in both the forward link and reverse link utilizing OFDM communications. The term forward link refers to the communication link from the base stations 120 a or 120 b to the user terminal 110, and the term reverse link refers to the communication link from the user terminal 110 to the base stations 120 a or 120 b. Both the base stations 120 a and 120 b and the user terminal 110 may allocate resources for channel and interference estimation. For example, both the base stations 120 a and 120 b and the user terminal 110 may broadcast pilot signals that are used be the corresponding receivers for channel and interference estimation.

The wireless communication system 100 can include a set of sub-carriers that span an operating bandwidth of the OFDMA system. Typically, the sub-carriers are equally spaced. The wireless communication system 100 may allocate one or more sub-carriers as guard bands, and the system 100 may not utilize the sub-carriers within the guard bands for communications with the user terminal 110.

In one embodiment, the wireless communication system 100 can include 2048 sub-carriers spanning an operating frequency band of 20 MHz. A guard band having a bandwidth substantially equal to the bandwidth occupied by six sub-carriers can be allocated on each end of the operating band. Therefore, in this embodiment, over 2000 sub-carriers are available for allocation to communications with the user terminal 110.

The wireless communication system 100 can be configured to partition the operating band into a plurality of operating segments, each of which can include at least one sub-carrier. The wireless communication system 100 can partition the forward link and reverse links to be identical. Alternatively, the forward link and reverse link segment definitions can be distinct.

The segments can each have a distinct set of sub-carriers such that no sub-carrier is allocated to more than one segment. In another embodiment, segments may have overlapping sub-carrier assignments. The segments can be contiguous frequency bands within the operating band or can be non-contiguous bands within the operating band. In one embodiment, each segment can span at least 16 sub-carriers or a multiple of 16 sub-carriers, although not all of the sub-carriers may be allocated to the same segment. Additionally, the segments may not be equally sized, and segments nearer the edge of the operating band may be smaller than segments closer to the center of the operating band.

In one embodiment, the wireless communication system 100 can be configure to partition a plurality of global segments, where each global segment has a bandwidth that spans a substantial fraction of the total operating band. Each of the global segments typically includes a non-contiguous subset of the total set of sub-carriers. In one embodiment, two global segments may be defined, with odd sub-carriers allocated to a first global segment and even sub-carriers allocated to a second global segment. In another embodiment, three global segments can be defined, with each global segment assigned every third sub-carrier in the operating band. Of course, the global segments do not need to have equally spaced sub-carriers, and do not need to span substantially the entire operating band. For example, two global segments can be defined that span one-half of the operating band, with sub-carriers in the half of the operating band alternately assigned to the global segments. Various other segment partitions may be defined, and the disclosure is not limited to any particular segment partition.

The wireless communication system 100 can also be configured to partition the operating band into one or more local segments. In one embodiment, each of the local segments can include a contiguous subset of all of the sub-carriers in the operating band. In another embodiment, at least one local segment can include a non-contiguous subset of sub-carriers. In one embodiment, each of the sub-carriers in the local segment can be within a coherent bandwidth of any other sub-carrier assigned to the same local segment. The coherent bandwidth corresponds to the bandwidth in which no substantial frequency selective fading occurs relative to another frequency within the band. For example, an embodiment can partition the operating band into multiple segments each having a bandwidth of approximately 1.25. MHz.

For example, the International Telecommunication Union (ITU) defines a channel model designated the Ped-B channel. This, channel model has a coherent bandwidth on the order of hundreds of kilohertz. Thus, a local segment can have a bandwidth that is less than the coherent bandwidth of the Ped-B channel model. With such a local segment constraint, the resource assignments within any particular local segment are relatively frequency non-selective. That is, a channel estimate within one local segment can be valid for any combination of sub-carriers within the local segment. For example, a wireless communication system 100 with an operating bandwidth of 20 MHz can partition the band into local segments of approximately 1.25 MHz each.

In one embodiment, the operating band can be partitioned into a predetermined number of local segments, each having substantially equal number of contiguous sub-carriers. In another embodiment, the wireless communication system 100 can include both global and local segments. For example, the wireless communication system 100 can define two global segments, with sub-carriers alternately assigned to each of the global segments. The wireless communication system 100 can select one of the global segments and can further partition the selected global segment into a plurality of local segments.

The wireless communication system 100 can include one more schedulers that are configured to allocate sub-carrier resource assignments to the various communication links within the system. For example, the wireless communication system 100 can include one or more schedulers at each of the base stations 120 a and 120 b. In one embodiment, each of the base stations 120 a and 120 b can include a first scheduler configured to schedule forward link sub-carrier assignments within the coverage area and a second scheduler configured to schedule reverse link sub-carrier assignments within the coverage area. Because each individual user terminal 110 typically has no knowledge regarding the sub-carrier assignments of other user terminals 110 within a particular coverage area, it may be advantageous for the wireless communication system 100 to implement a centralized reverse link scheduler for each coverage area located at the base stations 120 a and 120 b.

The scheduler can be configured to determine a resource assignment, including sub-carriers and corresponding segments, based in part on the channel characteristics experienced by the communication device. For example, the forward link scheduler can be configured to assign sub-carriers and segments based on the channel characteristics experienced by the base-station, for example 120 a, when communicating with a particular user terminal 110. Similarly, the reverse link scheduler can be configured to adding sub-carriers and segments to each user terminal 110 based in part on the channel characteristics experienced by the reverse link signal.

The schedulers can determine the channel characteristics on the forward and reverse links based on channel analysis, channel characteristic reporting, or a combination of channel analysis and reporting. The schedulers can be configured to assign the sub-carriers and segments to a communication link that exhibit the greatest signal level or that have the lowest interference. The scheduler can determine the number of sub-carriers assigned to a particular communication link based on a variety of factors, including the bandwidth of the signal communicated. The scheduler can also take into account other scheduling criteria, such as fairness, signal latency constraints, and other criteria, when assigning segments and sub-carriers to a communication link.

The wireless communication system 100 can maintain some level of interference diversity between the various communication channels by implementing frequency hopping. A communication link, such as a forward link signal transmitted by a base station 120 a or 120 b, or a reverse link signal transmitted by a user terminal 110, can be configured to frequency hop across a plurality of sub-carriers based on an initial sub-carrier assignment and a predetermined frequency hopping algorithm. The wireless communication system 100 can implement a frequency hopping algorithm that enforces frequency hopping within the assigned segments. Therefore, a forward link signal that is assigned a subset of carriers within a segment will perform frequency hopping within the segment in order to provide some level of interference diversity.

The wireless communication system 100 can be configured to Frequency Division Duplex (FDD) the forward and reverse links. In a FDD embodiment, the forward link is frequency offset from the reverse link. Therefore, forward link sub-carriers are frequency offset from the reverse link sub-carriers. Typically, the frequency offset is fixed, such that the forward link channels are separated from the reverse link sub-carriers by a predetermined frequency offset. The forward link and reverse link may communicate simultaneously, or concurrently, using FDD. In an FDD system, channel estimates determined for the forward or reverse link signals are typically not accurate channel estimates for the complementary FDD reverse or forward link channels. Thus, in FDD systems, channel characteristic reporting may be used to communicate channel characteristics to the appropriate scheduler.

In another embodiment, the wireless communication system 100 can be configured to Time Division Duplex (TDD) the forward and reverse links. In such an embodiment, the forward link and reverse links can share the same sub-carriers, and the wireless communication system 100 can alternate between forward and reverse link communications over predetermined time intervals. In TDD, the allocated frequency channels are identical between the forward and reverse links, but the times allocated to the forward and reverse links are distinct. A channel estimate performed on a forward or reverse link channel is typically accurate for the complementary reverse or forward link channel because of reciprocity.

The base stations 120 a and 120 b, and the user terminal 110 can be configured to broadcast a pilot signal for purposes of channel and interference estimation. The pilot signal can include broadband pilots such as a plurality of CDMA waveforms or a collection of narrow band pilots that span the overall spectrum. The broadband pilots could also be a collection of narrow band pilots staggered in time and frequency.

In one embodiment, the pilot signal can include a number of tones selected from the OFDM frequency set. For example, the pilot signal can be formed from uniformly spaced tones selected from the OFDM frequency set. The uniformly spaced configuration may be referred to as a staggered pilot signal.

The scheduler in the base station, 120 a or 120 b, can determine the channel characteristics in each of the segments based on the pilot signals. The recipient of the pilot signal, for example the user terminal 110 in the forward link direction, can determine an estimate of the channel and interference based on the received pilot signal. Additionally, the user terminal 110 can determine an estimate of the signal quality of the received signal, such as by determining a received signal to noise ratio (SNR). The signal quality of the received signal can be quantified as a channel quality indicator (CQI) value, which can be determined, in part based on the estimated channel and interference. In a wireless communication system 100 implementing multiple operating segments, the user terminal 110 can determine a channel and interference estimate corresponding to each of the operating segments and determine one or more CQI values based on the various channel and interference estimates.

The user terminal 110 can report a CQI value back to the base station, for example 1.0 a, and a scheduler in the base station 120 a can compare the CQI value for each of the operating segments to determine the segment(s) to allocate to the user terminal 110. The user terminal 110 can report the CQI directly in a reporting message or can generate a reporting message that includes data and information derived from the CQI value. For example, the user terminal 110 can be configured to determine the segment having the greatest CQI value and report the CQI value and identity of the corresponding segment. As will be discussed in greater detail below, the user terminal 110 can be configured to report the CQI value or related reporting message regularly, on an assigned basis, or on a probabilistically determined basis.

The wireless communication system 100 can implement a retransmission process, such as a Hybrid Automatic Repeat Request (HARQ) algorithm. In such a system, a transmitter may send an initial transmission at a first data rate and may send a subsequent retransmissions due to unsuccessful receipt at lower rates. HARQ incremental redundancy retransmission schemes can improve system performance in terms of providing early termination gain and robustness. However, improvements attributable to segment sensitive scheduling can be reduced if the scheduled transmission is based on out-dated information, which may occur in HARQ systems. If the segments and sub-carriers are not reallocated for retransmissions of an HARQ protocol, the segment which has high SNR at the time of the first transmission may get faded and results in a loss in performance.

Thus, in one embodiment, the wireless communication system 100 can be configured to re-determine the channel characteristics and can re-schedule sub-carrier and segments assigned to a particular communication link for HARQ retransmissions. Alternatively, the probability of channel fade occurring in the duration of the longest retransmission duration of a HARQ protocol, and the probability of a HARQ re-transmission occurring during channel fade may be sufficiently low. In such a situation, the wireless communication system may not reschedule sub-carriers and segments for HARQ retransmissions and may allow the communication link to experience a slight degradation if a channel fade should occur during the HARQ retransmissions.

FIG. 2 is a simplified functional block diagram of an embodiment of an OFDMA transmitter 200 such as can be incorporated within a base station of the wireless communication system of FIG. 1. The following discussion describes an embodiment in which the transmitter 200 is implemented in a base station of a wireless communication system configured for OFDMA communications. The transmitter 200 is configured to transmit one or more OFDMA signals to one or more user terminals. The transmitter 200 includes a data buffer 210 configured to store data destined for one or more receivers. The data buffer 210 can be configured, for example, to hold the data destined for each of the user terminals in a coverage area supported by the corresponding base station.

The data can be, for example, raw unencoded data or encoded data. Typically, the data stored in the data buffer 210 is unencoded, and is coupled to an encoder 212 where it is encoded according to a desired encoding rate. The encoder 212 can include encoding for error detection and Forward Error Correction (FEC). The data in the data buffer 210 can be encoded according to one or more encoding algorithms. Each of the encoding algorithms and resultant coding rates can be associated with a particular data format of a multiple format Hybrid Automatic Repeat Request (HARQ) system. The encoding can include, but is not limited to, convolutional coding, block coding, interleaving, direct sequence spreading, cyclic redundancy coding, and the like, or some other coding.

A wireless communication system implementing a HARQ algorithm can be configured to retransmit prior data that was not successfully decoded. The HARQ algorithm can be configured to provide a maximum number or retransmissions, and each of the retransmissions can occur at a lower rate. In other embodiments, the HARQ algorithm can be configured to transmit some of the retransmissions at the same rate.

The encoded data to be transmitted is coupled to a serial to parallel converter and signal mapper 214 that is configured to convert a serial data stream from the encoder 212 to a plurality of data streams in parallel. The scheduler 230 determines the number of sub-carriers, the identity of the sub-carriers, and the corresponding frequency segments for each user terminal. The scheduler 230 provides the resource allocation information to the signal mapper 214. The number of carriers allocated to any particular user terminal may be a subset of all available carriers. Therefore, the signal mapper 214 maps data destined for a particular user terminal to those parallel data streams corresponding to the data carriers allocated to that user terminal by the scheduler 230.

The output of the serial to parallel converter/signal mapper 214 is coupled to a pilot module 220 that is configured to allocate a predetermined portion of the sub-carriers to a pilot signal. In one embodiment, the pilot signal can include a plurality of equally spaced sub-carriers spanning substantially the entire operating band. The pilot module 220 can be configured to modulate each of the carriers of the OFDMA system with a corresponding data or pilot signal.

The output of the pilot module 220 is coupled to an Inverse Fast Fourier Transform (IFFT) module 222. The IFFT module 222 is configured to transform the OFDMA carriers to corresponding time domain symbols. Of course, a Fast Fourier Transform (FFT) implementation is not a requirement, and a Discrete Fourier Transform (DFT) or some other type of transform can be used to generate the time domain symbols. The output of the IFFT module 222 is coupled to a parallel to serial converter 224 that is configured to convert the parallel time domain symbols to a serial stream.

The serial OFDMA symbol stream is coupled from the parallel to serial converter 224 to a transceiver 240. In the embodiment shown in FIG. 2, the transceiver 240 is a base station transceiver configured to transmit the forward link signals and receive reverse link signals.

The transceiver 240 includes a forward link transmitter module 244 that is configured to convert the serial symbol stream to an analog signal at an appropriate frequency for broadcast to user terminals via an antenna 246. The transceiver 240 can also include a reverse link receiver module 242 that is coupled to the antenna 246 and is configured to receive the signals transmitted by one or more remote user terminals.

The scheduler 230 can be configured to receive reverse link signals, including the reverse link pilot signals and channel characteristic reporting messages, and determine the segments and sub-carriers to assign to the communication links for each of the user terminals. As described earlier, the scheduler 230 can use the reverse link pilot signals to determine the reverse link resource allocation. Additionally, the scheduler 230 can use the reverse link pilot signals to determine forward link resource allocation for TDD systems in which OFDMA system uses the same bandwidth for the forward and reverse links. In the embodiment shown in FIG. 2, the scheduler 230 can be used to schedule both forward and reverse link resources. In other embodiments, a separate scheduler can be used for the forward and reverse links.

The reverse link receiver module 242 can couple the reverse pilot signals to a channel estimator 232, shown in this embodiment as part of the scheduler 230. Of course, the channel estimator 232 is not limited to implementation within the scheduler 230 and may be implemented in some other module, such as the reverse link receiver 242. The channel estimator 232 can determine, for each of the user terminals broadcasting a reverse pilot signal, which segment has the highest signal power or highest Signal to Noise Ratio (SNR). Additionally, the channel estimator 232 can determine which of the segments has the lowest interference level.

High bandwidth communication links that are assigned to the global segments may not experience a significant improvement when the sub-carrier assignments over a resource allocation scheme that allocates resources based on highest average channel strength. Thus, in one embodiment, the channel estimator 232 determines the channel characteristics for each local segment and does not determine the channel characteristics for the global segments. Alternatively, the channel estimator 232 can be configured to determine an average channel strength for the global segments.

The channel estimator 232 can communicate the channel characteristic information to the resource scheduler 234 that operates to schedule the sub-carriers to the appropriate forward links based on the channel characteristic information. The resource scheduler 234 can also include reverse link scheduling messages on one or more overhead channels in the OFDMA system.

In one embodiment, the wireless communication system can implement an assignment algorithm that minimizes the overhead associated with resource assignments. The assignment method can be referred to as “sticky assignment.” The assignment algorithm may alternatively be referred to as persistent assignment or enduring assignment. In sticky assignment a user's assignment does not expire unless an explicit de-assignment message is received. An assignment message to other users that include a user's current resource ID is considered as a de-assignment message of the corresponding resource of this user. A user is assigned certain segment corresponding to a particular frequency band based upon favorable channel characteristics. This user will keep receiving or sending information over sub-carriers within the segment until a new assignment is received. Given limited scheduling overhead of N simultaneous messages, the system can potentially simultaneously schedule M users, where M is much greater than N.

Once resources are allocated to a particular communication link, the communication link can continue with that assignment. However, the sub-carrier assignments are not necessarily static. For example, the resource scheduler 234 can implement a channel tree that is a logical map of the available resources. The resources scheduler 234 can be configured to assign resources based on the logical structure of the channel tree. The resource scheduler 234 or some other module, such as the frequency hopping module 238, can map the logical resource assignment from the channel tree to a physical assignment that corresponds to physical sub-carriers of the OFDM system.

The channel tree can be organized in a branch structure with multiple branches. The branches eventually terminate in a lowest level of the tree, referred to as a leaf node or a base node. Every branch node in the channel tree can be assigned an identifying node index. Additionally, each leaf node or base node can be assigned a node index. Typically, the number of leaf nodes can correspond to the number of physical sub-carriers available in the OFDM system.

Every node includes a corresponding node index, and higher level branch nodes can be used to identify all of the nodes underneath the branch node in the channel tree. Thus, assigning a particular branch node to a particular communication link assigns all of the leaf nodes appearing underneath the particular branch node to that communication link.

Although each node of the channel tree, including each leaf node or base node, can be arbitrarily mapped to any physical resource, it may be advantageous to provide some mapping constraints on the channel tree. For example, the leaf nodes can be divided into groups, where each group of leaf nodes corresponds approximately to the number of sub-carriers within a segment. Thus, some of the leaf nodes can be divided into a group that corresponds to a global segment, while other leaf nodes can be divided into a group that corresponds to a local segment.

The branch nodes can thus be organized according to the grouping of the leaf nodes, and assigning a branch node corresponds to assigning all of the resources in nodes appearing underneath the branch node. It may be advantageous to have two distinct channel trees, one corresponding to resources assigned to global segments and another channel tree corresponding to the resources assigned to local segments.

If the resource scheduler 234 assigns a branch node sufficiently deep in the channel tree to a particular communication link based on the channel characteristics, the channel tree can be constrained such that all of the lower nodes underneath the branch node will be assigned to the same segment. This channel tree organization can simplify the mapping of the logical nodes to the physical resources.

The resource scheduler 234 or the frequency hopping module 238 can map the logical channel tree assignments to physical sub-carrier assignments. Therefore, the logical node assignments can remain stable while the physical sub-carriers mapped to the nodes can vary.

A frequency hopping module 238 can be configured to improve interference diversity by implementing frequency hopping within the assigned segment. The frequency hopper module 238 can, for example, implement a pseudorandom frequency hopping scheme for each assigned sub-carrier. The receiver can be configured to utilize the same frequency hopping algorithm to determine which sub-carriers are assigned to its corresponding link. For example, the frequency hopping module 238 can implement a frequency hopping algorithm that results in the same logical nodes being mapped to different physical sub-carriers at different instances.

The scheduler 230 can include a CQI receiver 236 configured to receive and process channel characteristic reporting messages generated by the user terminals and transmitted on the reverse link. Such reporting messages may be used to schedule the forward link assignments in FDD systems, or systems in which the reverse pilots do not sufficiently represent the forward link resources.

The manner and information included in the reporting messages are described in further detail below in relation to the description of the receiver embodiment. For the purposes of resource assignment, it is sufficient to describe the reporting messages as including some measure of channel characteristics, channel quality, segment preference, or some other indication that can be related to a segment preference.

The CQI receiver 236 is configured to receive the reporting messages and determine, based at least in part on the reporting messages, if the present resource allocation should be sustained or if the sub-carrier or segment allocations should be modified. The CQI receiver 236 can communicate the assignment information to the resource scheduler 234 that is configured to control the signal mapper 214 to implement the sub-carrier and segment assignments. The resource scheduler 234 can also report any new sub-carrier or segment assignments to the corresponding receiver. For example, the resource scheduler 234 can be configured to generate a control message that is communicated to the appropriate receiver using an overhead channel.

FIG. 3 is a simplified functional block diagram of an embodiment of a receiver 300. The receiver 300 can be, for example, part of a user terminal 110 shown in FIG. 1. The following discussion describes a receiver 300 implemented within a user terminal of an OFDMA wireless communication system using reporting messages for the determination of the forward link assignments.

The receiver 300 can include an antenna 356 coupled to a transceiver 350 configured to communicate over a wireless channel with the transmitter 200 shown in FIG. 2. The transceiver 350 can include a forward link receiver module 352 configured to receive the forward link wireless signals, via the antenna 356, and generate a serial baseband symbol stream.

The output of the receiver module 352 of the transceiver 350 is coupled to a serial to parallel converter 360 configured to convert the serial symbol stream to a plurality of parallel streams corresponding to the number of carriers in the OFDMA system.

The output of the serial to parallel converter 360 is coupled to a Fast Fourier Transform (FFT) module 362. The FFT module 362 is configured to transform the time domain symbols to the frequency domain counterpart.

The output of the FFT module 362 is coupled to a channel estimator 364 that is configure to determine a channel and interference estimate based in part on the forward link pilot signals. A carrier allocation module 380, alternatively referred to as a resource allocation module, can determine the sub-carriers assigned to the data and the sub-carriers assigned to the forward link pilot signals. The carrier allocation module 380 can determine the sub-carrier and segment assignments based in part on any assignment messages received. The carrier allocation module 380 can, for example, implement a frequency hopping algorithm to determine the current carrier assignment based on a past assignment. The carrier allocation module 380 is coupled to the channel estimator 364 and informs the channel estimator 364 of the sub-carrier and segment assignment.

The channel estimator 364 determines a channel and interference estimate based on the forward link pilot signals. The channel estimator 364 can be configured to estimate the channel and interference for each of the segments of the OFDMA system. The channel estimator 364 can determine an estimate using a least squares method, a maximum likelihood estimate, a combination of least squares and maximum likelihood estimate, and the like, or some other process of channel and interference estimation.

The output of the channel estimator 364 including the frequency domain transform of the received symbols and the channel and interference estimates is coupled to a demodulator 370. The carrier allocation module 380 can also inform the demodulator 370 of the sub-carrier frequencies allocated to data transmission. The demodulator 370 is configured to demodulate the received data carriers based in part on the channel and interference estimate. In some instances, the demodulator 370 may be unable to demodulate the received signals. As noted earlier, the demodulator 370 may be unsuccessful because the channel quality is inadequate and cannot support the transmitted rate of the data, or because degradation attributable to inadequate channel and interference estimation is sufficiently severe to result in decoding error.

If the demodulator 370 is unsuccessful, it can generate an indication of the inability to demodulate the received signals. The demodulator 370 can also provide an unsuccessful demodulation indication to the transmitter module 354 in the transceiver 350 for transmission back to the base station.

If the demodulator 370 is unsuccessful, the received data is dropped, and there is no need to couple any data to memory. If the demodulator 370 is successful, the demodulator 370 can be configured to couple the demodulated data to a parallel to serial converter 372 that is configured to convert the parallel demodulated data to a serial data stream. The output of the parallel to serial converter 372 is coupled to a data buffer 374 for further processing.

A channel quality indicator (CQI) module 390 can also be coupled to the channel estimator 364 and can use the values of pilot power, channel estimate, and interference estimate to determine a value of the CQI for each of the segments. In one embodiment, the CQI value is based in part on the SNR. The CQI module 390 couples the CQI value to the transmitter module 354, which can be configured to transmit the value to the base station using, for example, an overhead channel, control channel, or traffic channel.

The wireless communication system can implement a channel characteristic reporting scheme that is configured to minimize the amount of reporting messages that need to be communicated to the base stations. The wireless communication system can implement channel reporting schemes that require a user terminal to provide reporting messages on a periodic basis, an assigned basis, a probabilistically determined basis, or some other basis or combination of bases.

If the wireless communication system implements a periodic reporting scheme, the period can correspond to a predetermined time. The predetermined time can be based on a symbol timing, and can be based on a frame of symbols or multiple frames of symbols.

The CQI module 390 can be configured to report the CQI or an index of the segment corresponding to the best frame, if the reporting period spans multiple frames. In other embodiments, the CQI module 390 can be configured to average the CQI values over multiple frames and report the CQI or index of the segment having the best averaged CQI. In another embodiment, the CQI module 390 can be configured to report the CQI or index of the segments exhibiting improving CQI values. The CQI module 390 is not limited to any particular reporting criteria, and may use some other criteria for determining which segment or segments to report, and the information included with the reporting message.

If the feedback channel capacity and link budget are not limited in a system, each user terminal could transmit an array of CQI reporting messages for all frequency segments. In such a brute force reporting scheme, each user terminal reports every CQI value corresponding to every segment. However, this creates an enormous amount of unnecessary information.

To improve the amount of overhead used for reporting CQI, the wireless communication system can implement a reporting scheme where user terminals measure the forward link pilots and feedback the identity of the preferred frequency segment(s). In one embodiment, the user terminals determine a predetermined number of preferred segments and can report the identity of the predetermined number of segments to the scheduler in one or more reporting messages. The predetermined number can be a fixed number or can be varied, for example, based on a control message transmitted by the scheduler or a communication bandwidth desired by the user terminal.

The user terminal can generate reporting messages that report a CQI for as few as one preferred segment or CQI values for as many as all of the segments. In some embodiments, the number of segments identified in a reporting message can depend on a bandwidth occupied or desired in the communication link to the user terminal. For example, a user terminal having a communication bandwidth that is less than a bandwidth of a segment may report as few as one segment CQI value or a segment identity. A second user terminal having a communication bandwidth that is greater than the bandwidth of a single segment may report CQI values or segment identities for at least the number of segments needed to support the communication bandwidth.

In other embodiments, the wireless communication system may define more than one local segment size, or multiple local segments can be aggregated to form a larger segment. In such an embodiment, the user terminal can report a desired preferred segment of any size, and the segment size is not limited to a single segment size. In one embodiment, the user terminal can store a codebook with multiple segment sizes. The user terminal can determine a CQI value for each cluster or segment size defined in the codebook. The user terminal can report N of the best segment sizes based upon some predefined criteria, which may be part of the communication session or negotiated on a periodic basis.

The format of the reporting messages may be predetermined such that the user terminal reports the identities of the one or more segments in order of decreasing preference. Of course, other reporting message formats may be used. For example, the user terminal may report a CQI value and corresponding segment identity for each reported segment that is identified as a preferred segment.

The scheduler can use the reporting messages and other scheduling criteria to determine the tones or sub-carriers that are assigned to each of the user terminals. The wireless communication system can thus use the reporting messages to maintain communication links between base stations and user terminals over the segments that opportunistically provide advantageous performance.

In an embodiment of a reporting scheme implementing an efficient channel preference feedback algorithm, a user terminal can generate a reporting message using log₂L bits to indicate the segment with the best channel quality, where there are: L segments in the system. The user terminal transmits only the CQI of the best segment or only a segment index corresponding to the best segment in the feedback reporting message. The user terminal does not need to report L-1 CQI values corresponding to segments with lesser CQI values.

The CQI module 390 can further reduce the feedback rate by implementing thresholding logic in best segment reporting. Given a long term average channel quality in SNR, the CQI module 390 can compare the SNR corresponding to the best segment against the average SNR and choose not to report the CQI corresponding to the best segment unless it is a predetermined value, Δ, above the average. For example, the CQI module 390 can generate the reporting message if the CQI corresponding to the best segment is Δ dB above the average.

Thus, the CQI module 390 can have the opportunity to transmit a reporting message on a periodic basis or on an assigned basis and may selectively not transmit the reporting message based on the thresholding logic. For example, the CQI module 390 may be allowed to transmit a reporting message in a predetermined time slot that occurs each reporting interval, which can be, for example 15 ms. Alternatively, the CQI module 390 can be assigned a reporting time based on a round robin allocation of reporting slots to each of the user terminals in a base station coverage area. The CQI module 390 can implement thresholding logic to further reduce the instances of reporting messages regardless of the underlying reporting timing. In other embodiments, the CQI module 390 can be configured to generate and transmit a reporting message when the thresholding logic is satisfied.

This thresholding mechanism can provide a manner for a scheduler to balance the segment sensitive scheduling gain and reverse link feedback capacity. A scheduler in the wireless communication system can broadcast or multicast the desired threshold level, Δ, to user terminals based on reverse link feedback channel loading. High thresholds would lead to less reporting and low thresholds would lead to more reporting.

Alternatively, the scheduler can broadcast or multicast a desired reporting rate directly for example, the scheduler in the base station can transmit a desired percentage of time a user terminal is allowed to report the best segment. Each CQI module 390 in a user terminal can translate the desired reporting rate into a A dB threshold based on historical channel characteristic statistics maintained by the user terminal. For example, the CQI module 390 can collect the CQI values determines for each of the segments and can generate a distribution of the CQI values over time. The CQI module 390 can, for example, generate a Cumulative Distribution Function (CDF) based on the historical values. The CQI module 390 can then determine a threshold based on the desired reporting percentage and the CDF. For example, a reporting rate of 0.3 can corresponds to a 70% CDF quantile and Δ=5 dB reporting threshold. The CDF maintained by each CQI module 390 can be distinct, because they are established based on the channel characteristics experienced by the user terminal. Furthermore, the CDF may change over time, as the channel characteristics experienced by the user terminal change, for example, due to mobility or changes in the multipaths in the environment.

If HARQ is deployed in a system, the CQI module 390 can be configured to include the average CQI across all frequency segment the feedback reporting message. Although the conservative CQI will lead to the scheduling of low spectral efficiency transmission, early termination of HARQ is likely to retain a substantial fraction of the achievable capacity gain given reasonable HARQ granularity. This approach also improve the robustness of segment sensitive scheduling in the cases when the scheduled segment is not the best one and may possibly be a poor selection, because of, for example, channel decorrelation between channel measurement time and the actual transmission time, measurement mismatch, or some other factors.

FIG. 4 is a simplified flowchart of an embodiment of a method 400 of segment sensitive scheduling. The method 400 can be performed, for example, by the scheduler in an OFDMA wireless communication system, such as a scheduler in a base station shown in the system of FIG. 1. For example, the scheduler shown in the base station transmitter of FIG. 2 can be configured to perform the method 400. The scheduler can perform the method 400 for each of the users. For example, the scheduler can perform the method for each of the forward link and reverse links established between a base station and user terminals in the base station coverage area.

The method 400 begins at block 402 where the scheduler partitions the operating band into a plurality of segments. The wireless communication system can define the segments, and the segments can include one or more global segments and one or more local segments. The global segments can include a subset of the sub-carriers of the OFDMA system that span substantially a large fraction of the operating band. The global segments typically are assigned non-contiguous frequency spans comprising one or more sub-carriers. The local segments can be contiguous or non-contiguous bands that include one or more sub-carriers. The local segments typically have a bandwidth that is less than a coherent bandwidth of the wireless channel. In some cases the segments may be pre-partitioned in a predetermined manner and known to both the base station and mobile station. As such, this functionality may be omitted.

The scheduler need not perform any actual physical partitioning of the operating band, but may instead, merely account for the various segments and the sub-carriers associated with each segment. The scheduler typically associates each sub-carrier with only one segment, and each segment includes a distinct subset of sub-carriers.

The scheduler proceeds to block 410 and determines user data constraints. Such user data constraints can include data latency constraints, bandwidth constraints, and other constraints that may be associated with particular users or communication links. The scheduler can be configured to attempt to satisfy substantially all data constraints when scheduling the segment.

After receiving the data constraints, the scheduler proceeds to decision block 420 to determine if the channel for a particular user requires high bandwidth. In the context of the scheduler, the term high bandwidth refers to a user that requires a resource assignment that exceeds the bandwidth of a predetermined number of local segments. The predetermined number of local segments can be, for example, one, or can be some other number greater than one. High data rate users can require transmission of signals over a large fraction of the total bandwidth, which reduces the potential gain of scheduled transmission over average channel SNR.

If the user requires high bandwidth, the scheduler proceeds to block 430 and assigns the user to a global segment and assigns sub-carriers from the assigned global segment. The scheduler then proceeds from block 430 back to block 410.

If, at decision block 420 the scheduler determines that the user does not require high bandwidth, the scheduler proceeds to block 440 and determines a segment preference for the user and communication link. The scheduler can determine a segment preference based on channel analysis, channel characteristic reporting messages, or a combination of analysis and reporting messages.

In one embodiment, the scheduler can determine a channel estimate for each local segment in the operating band based on a pilot signal transmitted by the user terminal. The scheduler can compare all of the channel estimates to determine the segment preference as the segment that has the best channel characteristics. For example, the scheduler can determine, based in part on the channel estimates, which of the segments has the highest SNR.

In another embodiment, the scheduler can receive reporting messages from some or all of the user terminals. The reporting messages can include a segment preference or can include channel characteristics that the scheduler can use to determine a segment preference.

After determining the segment preference for a particular user, the scheduler proceeds to decision block 450 to determine whether the segment preference differs from a previous segment preference for that same user.

If the scheduler determines that the segment preference has changed, the scheduler proceeds to block 460 and assigns a segment and sub-carriers from the segment to the communication link. In the forward link direction, the scheduler can assign a channel by controlling a signal mapper to map the data signal for the user terminal to the appropriate sub-carriers in the preferred segment. In the reverse link direction, the scheduler can generate a segment assignment message that identifies the segment and sub-carriers assigned to that user terminal. After segment assignment, the scheduler proceeds back to block 410.

The wireless communication system can implement sticky or persistent assignments. The user terminal can use the same assignment until it receives a de-assignment message. In one embodiment, the de-assignment message can be an assignment message to a distinct user terminal for a sub-carrier for which the user terminal is assigned.

If, at decision block 450, the scheduler determines that the segment preference has not changed, the scheduler proceeds to block 470. At block 470, the scheduler can provide some form of interference diversity by implementing frequency hopping. The scheduler can be configured to enforce frequency hopping within the assigned segment in order to maintain the advantages of segment sensitive scheduling. After enforcing the frequency hopping on the assigned sub-carriers, the scheduler proceeds back to block 410.

FIG. 5 is a simplified flowchart of an embodiment of a method 500 of channel characteristic reporting in a system implementing segment sensitive scheduling. As noted above, the scheduler can utilize reporting messages as part of the segment sensitive scheduling process. The manner in which reporting messages are generated and transmitted to the scheduler can affect the amount of overhead required to support reporting messages. The reporting method 500 can be performed, for example, by a user terminal of the wireless communication system of FIG. 1 to assist in scheduling of forward link OFDMA channels.

The method 500 begins at block 510 where the user terminal receives the forward link pilot signals. The user terminal proceeds to block 520 and determines channel characteristics for each of the predetermined local segments in the operating band. The user terminal can, for example, determine the signal level, interference level, SNR over the segment, or some other channel characteristic for each local segment. The user terminal can also determine channel characteristics, such as an average channel strength or average SNR for each of the global segments.

The user terminal proceeds to block 530 and determines a preferred segment from the various segments. A high bandwidth user may prefer a global segment to any local segment merely due to the ability of the global segment to satisfy the bandwidth requirements. If there are multiple global segments, the user terminal can determine a global segment having the greatest average SNR as the preferred segment.

Alternatively, fit the user terminal is assigned to a local segment or capable of assignment to a local segment, the user terminal determines which of the segments is the preferred segment. The user terminal can, for example, select the local segment that corresponds to the highest SNR or channel power. In another embodiment, the user terminal may select the segment having the least interference. In another embodiment, the user terminal can select a preferred segment based on a variety of factors.

After determining the segment preference, the user terminal proceeds to decision block 540 to determine whether a reporting constraint is satisfied. The user terminal can include a number of reporting constraints and may generate and transmit a reporting message only when a predetermined number of constraints are satisfied. The user terminal can limit the reporting messages using the reporting constraints in order to minimize the amount of reporting overhead communicated to the scheduler.

For example, the user terminal can limit reporting to messages that report SNR values greater than a predetermined threshold above an average channel SNR. The predetermined threshold can be static or can be communicated from the scheduler. Additionally, the user terminal can be limited to only reporting segment preferences that are distinct from the segment in which the user terminal is presently operating.

If the user terminal does not satisfy the reporting constraints, the user terminal returns to block 510 and does not generate a reporting message. Alternatively, if at decision block 540 the user terminal determines that the reporting constraints have been satisfied, the user terminal proceeds to block 550 and generates a reporting message.

The user terminal can, for example, generate a reporting message that identifies the preferred segment or a plurality of preferred segments. The user terminal can, for example, report an index corresponding to the preferred segment. The user terminal may also include in the reporting message other channel characteristics, such as an average CQI over all segments.

After generating the reporting message, the user terminal proceeds to block 560 and transmits the reporting message to the scheduler. For example, the user terminal can transmit the reporting message or messages to a base station on a reverse link overhead channel. The user terminal returns to block 510 to repeat the channel analysis and reporting method 500.

Methods and apparatus for segment sensitive scheduling have been described. An OFDMA wireless communication system can implement segment sensitive scheduling to improve the performance of the communication links. The wireless system can partition the operating band into a number of segments, including global segments and local segments. A scheduler in the system can be configured to assign a segment and sub-carriers within the segment to each communication link based on channel characteristics. The channel characteristics can be determined at the scheduler using channel analysis or can be determined at the receiver and fed back to the scheduler in one or more reporting messages.

Reporting constraints can be imposed on the reporting messages to limit the overhead needed to support the reporting messages. The reporting constraints can limit the amount of information reported and can limit the instances of reporting messages. For example, the reporting messages can be limited to reporting a CQI value or segment index for a segment preference. The reporting messages can be limited to reporting on a predetermined periodic basis or an assigned basis such as in round robin reporting where each user terminal in a base station coverage area reports one time before any user terminal transmits an updated reporting message. The reporting messages can also be limited to a probabilistic basis, where reporting is limited based on a probability that the user terminal will experience a preferred segment that is substantially better than an average channel characteristic.

The wireless communication system can improve the overall system performance by utilizing segment sensitive scheduling.

The various illustrative logical blocks, modules, and circuits described in connection with the embodiments disclosed herein may be implemented or performed with a general purpose processor, a digital signal processor (DSP), a Reduced Instruction Set Computer (RISC) processor, an application specific integrated circuit (ASIC), a field programmable gate array (FPGA) or other programmable logic device, discrete gate or transistor logic, discrete hardware components, or any combination thereof designed to perform the functions described herein. A general purpose processor may be a microprocessor, but in the alternative, the processor may be any processor, controller, microcontroller, or state machine. A processor may also be implemented as a combination of computing devices, for example, a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core, or any other such configuration.

The steps of a method, process, or algorithm described in connection with the embodiments disclosed herein may be embodied directly in hardware, in a software module executed by a processor, or in a combination of the two.

A software module may reside in RAM memory, flash memory, non-volatile memory, ROM memory, EPROM memory, EEPROM memory, registers, hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art. An exemplary storage medium is coupled to the processor such the processor can read information from, and write information to, the storage medium. In the alternative, the storage medium may be integral to the processor. Further, the various methods may be performed in the order shown in the embodiments or may be performed using a modified order of steps. Additionally, one or more process or method steps may be omitted or one or more process or method steps may be added to the methods and processes. An additional step, block, or action may be added in the beginning, end, or intervening existing elements of the methods and processes.

The above description of the disclosed embodiments is provided to enable any person of ordinary skill in the art to make or use the disclosure. Various modifications to these embodiments will be readily apparent to those of ordinary skill in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the disclosure. Thus, the disclosure is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein. 

1. An apparatus for c scheduling in a communication system including a plurality of sub-carriers spanning an operating frequency band, the apparatus comprising: a channel estimator configured to determine a channel estimate corresponding to each of a plurality of segments spanning the operating frequency band based on the pilot signal, each of the segments having a bandwidth less than a total bandwidth; a signal mapper configured to map data symbols to a subset of the plurality of sub-carriers in the communication system; and a scheduler coupled to the channel estimator and configured to determine a first preferred segment based on the channel estimates, select the subset of the plurality of sub-carriers from within the first preferred segment, and further configured to control the signal mapper to map the data symbols to the subset of the plurality of sub carriers.
 2. The apparatus of claim 1, further comprising a receiver module configured to receive reverse link pilot signals and wherein the scheduler is configured to select the subset of the plurality of sub-carriers for a forward link transmission based on the reverse link pilot signals.
 3. The apparatus of claim 1, wherein the pilot signals comprise reverse link pilot signals and the scheduler is configured to generate a reverse link resource assignment message for transmission to a user terminal based on the channel estimates.
 4. The apparatus of claim 1, wherein the scheduler is configured to select the first preferred segment as a segment having a largest signal to noise ratio determined from the pilot signals.
 5. The apparatus of claim 1, further comprising: a Channel Quality Indicator (CQI) receiver coupled to the receiver module and configured to process channel characteristic reporting messages received by the receiver to determine a second preferred segment and further configured to generate a resource assignment message based on the channel characteristic reporting messages.
 6. The apparatus of claim 1, further comprising a frequency hopper module configured to enforce a frequency hopping scheme within the first preferred segment. 